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Summary GacS/GacA is a conserved two‐component system that functions as a master regulator of virulence‐associated traits in many bacterial pathogens, including Pseudomonas spp., that collectively infect both plant and animal hosts. Among many GacS/GacA‐regulated traits, type III secretion of effector proteins into host cells plays a critical role in bacterial virulence. In the opportunistic plant and animal pathogen Pseudomonas aeruginosa, GacS/GacA negatively regulates the expression of type III secretion system (T3SS)‐encoding genes. However, in the plant pathogenic bacterium Pseudomonas syringae, strain‐to‐strain variation exists in the requirement of GacS/GacA for T3SS deployment, and this variability has limited the development of predictive models of how GacS/GacA functions in this species. In this work we re‐evaluated the function of GacA in P. syringae pv. tomato DC3000. Contrary to previous reports, we discovered that GacA negatively regulates the expression of T3SS genes in DC3000, and that GacA is not required for DC3000 virulence inside Arabidopsis leaf tissue. However, our results show that GacA is required for full virulence of leaf surface‐inoculated bacteria. These data significantly revise current understanding of GacS/GacA in regulating P. syringae virulence.

The Gram-negative opportunistic pathogen Pseudomonas aeruginosa ubiquitously inhabits soil and water habitats and also causes serious, often antibiotic resistant, infections in immunocompromised patients (e.g. cystic fibrosis). This versatility is mediated in part by a large repertoire of two-component regulatory systems that appear instrumental in the regulation of both virulence processes and resistance to antimicrobials. Major two-component regulatory system proteins demonstrated to regulate these diverse processes include PhoP-PhoQ, GacA-GacS, RetS, LadS, and AlgR, among others. Here, we summarize the current body of knowledge of these and other two-component systems that provides insight into the complex regulation of virulence and resistance in P. aeruginosa.

The virulence of Staphylococcus aureus is essentially determined by cell wall associated proteins and secreted toxins that are regulated and expressed according to growth phases and/or growth conditions. Gene expression is regulated by specific and sensitive mechanisms, most of which act at the transcriptional level. Regulatory factors constitute numerous complex networks, driving specific interactions with target gene promoters. These factors are largely regulated by two-component regulatory systems, such as the agr, saeRS, srrAB, arlSR and lytRS systems. These systems are sensitive to environmental signals and consist of a sensor histidine kinase and a response regulator protein. DNA-binding proteins, such as SarA and the recently identified SarA homologues (SarR, Rot, SarS, SarT, SarU), also regulate virulence factor expression. These homologues might be intermediates in the regulatory networks. The multiple pathways generated by these factors allow the bacterium to adapt to environmental conditions rapidly and specifically, and to develop infection. Precise knowledge of these regulatory mechanisms and how they control virulence factor expression would open up new perspectives for antimicrobial chemotherapy using key inhibitors of these systems.

The two-component regulatory system comprised of the sensor kinase, GacS, and its response regulator, GacA, is involved in regulation of secondary metabolism and many other aspects of bacterial physiology. Although it is known that the sensor kinases RetS and LadS feed into the GacS/GacA system, the mechanism through which this occurs is unknown, as are the protein-protein interactions in this system. To characterize and define these interactions, we utilized a bacterial two-hybrid system to study the interactions of GacS and GacA from Pseudomonas fluorescens CHA0. Domains of GacA and GacS, identified through bioinformatics, were subcloned and their ability to interact in vivo was investigated. We found that the entire GacA molecule is required for GacA to interact with itself or GacS. Furthermore, the HisKA/HATPase/REC domains of GacS together are responsible for GacS interacting with GacA, while the HAMP domain of GacS is responsible for GacS interacting with itself. In addition, homologs of Pseudomonas aeruginosa hybrid sensor kinases, RetS and LadS, were identified in P. fluorescens, and shown to interact with GacS, but not GacA.

Conservons are operons that encode unusual regulatory systems found in bacteria of the phylum Actinomycetota. These regulatory systems are composed of four core proteins: a sensor histidine kinase-like protein (CvnA homolog), an MglB-type roadblock protein (CvnB homolog), a protein containing a domain of unknown function (CvnC homolog), and a small Ras-like GTPase (CvnD homolog). Based on their conserved small GTPase components and their phylogenetic distribution, we propose that the systems encoded by conservons should be known as ctinobacterial rotein ystems (AGPSs). The signal transduction path through AGPSs remains poorly understood, and some AGPSs have additional accessory proteins (CvnE and CvnF homologs) of unknown function. In this work, we show that AGPS accessory proteins are present when the cognate histidine kinase protein (CvnA homolog) lacks an extracytoplasmic sensory domain. It was previously shown that the Cvn8 AGPS of controls the expression of multiple pathways for specialized metabolism. The Cvn8 AGPS also contains an accessory protein, CvnF8. Through protein modeling, we found that CvnF8 may share an interaction interface with the histidine kinase CvnA8, prompting the hypothesis that CvnF8 may act as a modulator of CvnA8 activity. Consistent with this hypothesis, we found that when co-expressed in a heterologous host, CvnA8 and CvnF8 were purified as a stable complex. In a purified system, CvnF8 strongly stimulated the ATPase activity and autophosphorylation of CvnA8. Taken together, these findings indicate that CvnF family accessory proteins likely serve as sensors and/or modulators of histidine kinases of AGPSs found broadly in Actinomycetota. Many lineages of bacteria in the phylum Actinomycetota contain conserved operons (conservons) that encode an unusual type of regulatory system whose function is poorly understood. These lineages include pathogens such as and members of the genus that produce valuable natural products. These regulatory systems are composed of four proteins, including a sensor histidine kinase and a small Ras-like GTPase. We propose that these regulatory systems be known as actinobacterial G protein systems (AGPSs). We show that some AGPSs include accessory proteins that are only found with partner histidine kinases that lack sensory domains. We demonstrate that one such accessory protein can control the activity of its cognate histidine kinase. Our findings indicate that these CvnF-family accessory proteins likely serve as sensory inputs for AGPSs found broadly in Actinomycetota. This work sheds light on the initial steps of signal transduction within these unusual regulatory systems.

The classical TCS system in bacterial signal transduction is composed of two proteins—a histidine kinase and its cognate response regulator. More and more studies have revealed the presence of accessory proteins that can modulate the histidine kinase activity and affect signal transduction, but their mechanisms remain largely elusive. This study unveils a previously unrecognized mechanism by which bacterial accessory lipoproteins mediate TCS activation. We provide compelling evidence that QseG directly interacts with QseE through an evolutionarily conserved structural interface, readily and sufficiently activating QseE’s autokinase activity and downstream signaling. Given the essential role of QseEF in bacterial virulence and stress adaptation, our findings pave the way for the development of antimicrobial strategies targeting this conserved lipoprotein-mediated activation mechanism.

Multidrug efflux systems not only cause resistance against antibiotics and toxic compounds but also mediate successful host colonization by certain plant‐associated bacteria. The genome of the nitrogen‐fixing soybean symbiont Bradyrhizobium japonicum encodes 24 members of the family of resistance/nodulation/cell division (RND) multidrug efflux systems, of which BdeAB is genetically controlled by the RegSR two‐component regulatory system. Phylogenetic analysis of the membrane components of these 24 RND‐type transporters revealed that BdeB is more closely related to functionally characterized orthologs in other bacteria, including those associated with plants, than to any of the other 23 paralogs in B. japonicum. A mutant with a deletion of the bdeAB genes was more susceptible to inhibition by the aminoglycosides kanamycin and gentamicin than the wild type, and had a strongly decreased symbiotic nitrogen‐fixation activity on soybean, but not on the alternative host plants mungbean and cowpea, and only very marginally on siratro. The host‐specific role of a multidrug efflux pump is a novel feature in the rhizobia-legume symbioses. Consistent with the RegSR dependency of bdeAB, a B. japonicum regR mutant was found to have a greater sensitivity against the two tested antibiotics and a symbiotic defect that is most pronounced for soybean.

Pseudomonasaeruginosa is a major causative agent of hospital-acquired infections and infections in cystic fibrosis patients. Treatment of P. aeruginosa is complicated by the presence of intrinsic and acquired multidrug-resistant isolates. Polymyxin B has often been used as the last option to treat the multidrug-resistant isolates. However, polymyxin B-resistant clinical isolates have been increasingly reported worldwide. To understand molecular details of polymyxin resistance we characterized polymyxin B-resistant clinical isolate of P. aeruginosa. The clinical isolate grew with 4 μg mL⁻¹ of polymyxin B while a reference P. aeruginosa PAO1 grew with 0.25 μg mL⁻¹. Polymyxin B susceptibility was restored (minimal inhibitory concentration from 8 to 0.5 μg mL⁻¹) by an intact clone of pmrAB, but not by an intact clone of phoPQ or the cloning vector. DNA sequence analysis of pmrB from the resistant isolate revealed a single nucleotide substitution (T to C) substituted methionine to threonine at position 292 of PmrB. Involvement of this amino acid substitution in polymyxin B resistance was confirmed by complementation of a pmrAB null-mutant strain with the pmrAB containing the amino acid substitution. These results suggest that amino acid substitution in PmrB is one mechanism of polymyxin B resistance in clinical isolates of P. aeruginosa.

Modification of the outer membrane charge by a polymyxin B (PMB)-induced PmrAB two-component system appears to be a dominant phenomenon in PMB-resistant Acinetobacter baumannii . PMB-resistant variants and many clinical isolates also appeared to produce outer membrane vesicles (OMVs). Genomic, transcriptomic, and proteomic analyses revealed that upregulation of the pmr operon and decreased membrane-linkage proteins (OmpA, OmpW, and BamE) are linked to overproduction of OMVs, which also promoted enhanced biofilm formation. The addition of OMVs from PMB-resistant variants into the cultures of PMB-susceptible A. baumannii and the clinical isolates protected these susceptible bacteria from PMB. Taxonomic profiling of in vitro human gut microbiomes under anaerobic conditions demonstrated that OMVs completely protected the microbial community against PMB treatment. A Galleria mellonella- infection model with PMB treatment showed that OMVs increased the mortality rate of larvae by protecting A. baumannii from PMB. Taken together, OMVs released from A. baumannii functioned as decoys against PMB. Wrapped in a thick, protective outer membrane, Acinetobacter baumannii bacteria can sometimes cause serious infections when they find their way into human lungs and urinary tracts. Antibiotics are increasingly ineffective against this threat, which forces physicians to resort to polymyxin B, an old, positively-charged drug that ‘sticks’ to the negatively-charged proteins and fatty components at the surface of A. baumannii . Scientists have noticed that when bacteria are exposed to lethal drugs, they often react by releasing vesicles, small ‘sacs’ made of pieces of the outer membranes which can contain DNA or enzymes. How this strategy protects the cells against antibiotics such as polymyxin B remains poorly understood. To investigate this question, Park et al. examined different strains of A. baumannii , showing that bacteria resistant to polymyxin B had lower levels of outer membrane proteins but would release more vesicles. Adding vesicles from resistant strains to non-resistant A. baumannii cultures helped cells to survive the drugs. In fact, this protective effect extended to other species, shielding whole communities of bacteria against polymyxin B. In vivo, the vesicles protected bacteria in moth larvae infected with A. baumannii , leading to a higher death rate in the animals. Experiments showed that the negatively-charged vesicles worked as decoys, trapping the positively-charged polymyxin B away from its target. Taken together, the findings by Park et al. highlight a new strategy that allows certain strains of bacteria to protect themselves from antibiotics, while also benefitting the rest of the microbial community.

Pseudomonas aeruginosa is a metabolically versatile environmental pathogen whose virulence relies on coordinated expression of catabolic genes, particularly the histidine utilization ( hut ) operon. Disruption of the hut operon reduces virulence, but the underlying mechanism remains rudimentary. Here, we genetically characterized the histidine-responsive transcriptional factor HutC in P. aeruginosa PAO1, alongside HutC in the non-pathogenic strain Pseudomonas fluorescens SBW25. Two important features emerged. First, HutC recognizes two distinct DNA-binding motifs with little sequence similarity; notably, a noncanonical-binding site was identified in the hutF promoter of SBW25 but was absent in PAO1. Second, HutC exhibits low-affinity binding to genes beyond histidine catabolism and contributes to the expression of multiple virulence traits. These findings identify HutC as a local regulator linking histidine catabolism with virulence and as a unique prokaryotic model for studying how noncanonical transcriptional factor-DNA interactions achieve binding specificity, a phenomenon so far investigated only in eukaryotes.